This is an easy problem involving 2D vectors. The sine of the angle between two vectors is related to the cross-product between the two vectors. And "above" or "below" is determined by the sign of the vector that's produced by the cross-product: if you cross two vectors A and B, and the cross-product produced is positive, then A is "below" B; if it's negative, A is "above" B. See Mathworld for details.

Here's how I might code it in Java:

```
package cruft;
import java.text.DecimalFormat;
import java.text.NumberFormat;
/**
* VectorUtils
* User: Michael
* Date: Apr 18, 2010
* Time: 4:12:45 PM
*/
public class VectorUtils
{
private static final int DEFAULT_DIMENSIONS = 3;
private static final NumberFormat DEFAULT_FORMAT = new DecimalFormat("0.###");
public static void main(String[] args)
{
double [] a = { 1.0, 0.0, 0.0 };
double [] b = { 0.0, 1.0, 0.0 };
double [] c = VectorUtils.crossProduct(a, b);
System.out.println(VectorUtils.toString(c));
}
public static double [] crossProduct(double [] a, double [] b)
{
assert ((a != null) && (a.length >= DEFAULT_DIMENSIONS ) && (b != null) && (b.length >= DEFAULT_DIMENSIONS));
double [] c = new double[DEFAULT_DIMENSIONS];
c[0] = +a[1]*b[2] - a[2]*b[1];
c[1] = +a[2]*b[0] - a[0]*b[2];
c[2] = +a[0]*b[1] - a[1]*b[0];
return c;
}
public static String toString(double [] a)
{
StringBuilder builder = new StringBuilder(128);
builder.append("{ ");
for (double c : a)
{
builder.append(DEFAULT_FORMAT.format(c)).append(' ');
}
builder.append("}");
return builder.toString();
}
}
```

Check the sign of the 3rd component. If it's positive, A is "below" B; if it's negative, A is "above" B - as long as the two vectors are in the two quadrants to the right of the y-axis. Obviously, if they're both in the two quadrants to the left of the y-axis the reverse is true.

You need to think about your intuitive notions of "above" and "below". What if A is in the first quadrant (0 <= θ <= 90) and B is in the second quadrant (90 <= θ <= 180)? "Above" and "below" lose their meaning.

The line then rotates from its
starting position, and I need to
calculate the angle from its starting
position to current position. E.g if
it has rotated clockwise, it is
positive rotation; if
counterclockwise, then negative. (Or
vice versa.)

This is exactly what the cross-product is for. The sign of the 3rd component is positive for counter-clockwise and negative for clockwise (as you look down at the plane of rotation).